SU1106878A2 - Percussive action machine - Google Patents

Abstract

I. SHOCK ACTION MACHINE by author. St. No. 1052627, characterized in that, in order to increase the efficiency of the machine by ensuring its reversal, it is equipped with an average variable for changing the shape of the air pressure diagram in the working cavity of the pulsator. 2. The machine according to claim 1, wherein the means for changing the shape of the air pressure diagram in the working cavity of the pulsator is made in the form of a closed chamber communicating with the working cavity of the pulsator by means of a channel with a driver installed in it. 3. The machine according to claim 1, characterized in that the means for changing the shape of the air pressure diagram in the working cavity of the pulsator is made in the form of an additional opening in the side wall of the body of the pulsator with a switch. 4. Machine on PP. 2 and 3, characterized in that the switch is designed as a plug valve or valve. (L 7 O5 oo oo

Description

The invention relates to the field of impact machines, and more specifically to machines intended for use in construction, for example, self-propelled impact machines for penetrating wells in the ground. According to the main author. St. No. 1052627 is known percussion machine, which consists of a body, a working tool, a striker, a duct hose, and a pneumatic pulsator with a drive. The drummer is placed in the inner plane of the housing and divides this cavity into two working chambers: the front and rear. The front working chamber formed by the walls of the body, the drummer and the shank of the working tool is communicated by a channel of small bore with the rear working chamber formed by the walls of the body and the hammer. The rear working chamber is continuously communicated with the working cavity of the pneumatic pulsator by means of the air inlet hose. Pneumatic pulsator soyoit from the body of the pulsator and displacer. The displacer is coupled to a motor, such as an electric one, by means of a reciprocating mechanism. A compensating hole is provided on the side wall of the pulsator housing, through which the pulsator's working cavity can communicate with the external medium (atmosphere) ... A known machine works as follows. When the engine is turned on, the displacer of the pneumatic actuator moves reciprocally along the body axis according to a periodic law. At the same time, the air pressure in the working cavity of the pulsator, in the air inlet sleeve and in the rear working chamber of the machine varies (at steady state) according to a certain periodic law with a period equal to the period of movement of the displacer. Taking into account that the front and rear working chambers of the machine are interconnected by a channel of small flow area, the pressure in these chambers does not match. Under the action of a periodically varying pressure difference in the front and rear working chambers, the striker performs a reciprocating motion and strikes the shank of the working tool. When the masks inevitably work, air leaks from the pulsator's working cavity are compensated for through the compensation hole made on the side wall of the pulsator housing. The machine has many very valuable performance qualities. It is extremely simple, has a rather high efficiency. Due to its tightness, this machine is not sensitive to clogging and can work in any environment, for example under water. Due to the absence of compressed air exhaust from the working chambers, the machine has improved noise characteristics. This machine has a fairly high specific power. 1. The disadvantage of the known machine is that it is not equipped with the means that ensure their reversal. The need for reversal arises, for example, when creating self-propelled machines for punching wells in the ground (machines like pneumatic punches). The aim of the invention is to increase the efficiency of the machine by reversing it. This goal is achieved by the fact that the proposed mask is equipped with means that allow changing the shape of the air pressure diagram in the working cavity of the pulsator, which can be made in the form of a closed chamber communicated with the working cavity of the pulsator through a channel with a switch installed in it, or in the form of an additional holes in the side wall of the case of the pulsator with a switch. The switch can be made in the form of a cork valve or valve. FIG. 1 and 2 schematically represent two variants of the implementation of a reversible percussion machine. The machine shown in FIG. 1, consists of a hollow body 1, a hammer 2, movably placed inside the body, an air supplying sleeve 3 and a pneumatic pulsator. The drummer 2 divides the internal cavity of the body into two working chambers: front 4 and rear 5. The front and rear working chambers are connected to each other by a channel (not shown) of a small flow area, which can be performed, for example, in the drummer in the form of an aperture, slit and etc. The main elements of the pneumatic pulsator are the pulsator body 6 and the displacer 7. The pulsator's working cavity 8, formed by the walls of the body and the displacer, is continuously communicated with the rear working frame 5 by means of the air supplying sleeve 3. The displacer can move along the axis of the body. The reciprocating movement of the displacer is carried out using a special mechanism, such as a crank-rod. The drive can be applied to any type of engine, such as electric. A through compensation hole 9 is made on the side wall of the body 6 of the pulsator. The pneumatic pulsator is equipped with an additional closed chamber 10 of the calculated volume, which is connected via channel 11 to the working cavity 8 of the pulsator. There is a device 12 that provides the opening and closing of the specified channel, which can be made in the form of a cork valve, valve, etc.

The reversible percussion machine shown in FIG. 1, works as follows.

When the engine is turned on, the displacer 7 of the pneumatic pulsator moves reciprocatingly

corps according to the periodic law. At the same time, the air pressure in the working cavity 8 of the pulsator, in the air inlet sleeve 3 and in the rear working chamber 5 of the machine varies (at steady state) according to some periodic law with a period equal to the period of movement of the displacer. Since the front 4 and rear 5 working chambers of the machine are connected by channels with a small flow area, the pressure in these chambers does not match. Under the action of periodically changing ush, its pressure difference in channels 4 and 5, the striker 2 reciprocates and, with the channel P closed, strikes the working tool of the front part of the body 1. Under the action of these blows, the body 1 of the machine is inserted into the ground. The reverse movement of the hull 1 is prevented by frictional forces between hull 1 and the ground. As a result, a well with compacted walls is formed. During operation of the machine, the working cavity 8 of the pulsator during each working cycle is connected through the compensation hole 9 with the environment.

Switching the machine from the "Forward mode to the" Reverse mode is carried out in a simple way. For this purpose, using the device 12, the channel 11 opens, indicating the working cavity 8 of the pulsator with an additional chamber 10. As a result of adding the volume of the additional chamber 10 to the volume of the working cavity 8 of the pulsator, the degree of compression in the working cavity 8 of the pulsator is reduced by the calculated value . This leads to a change in the shape of the pressure diagram in the working cavity 8 of the pulsator and to a change in the mode of operation of the machine. In the Reverse Drive mode, the machine works in the same way as in the Forward Drive mode, with the only difference that drummer 2 strikes not the front part of housing 1, but the back one. Under the action of these blows, the machine moves the finished well in the opposite direction.

Thus, the machine is capable of piercing “blind wells” and can be returned from the well, for example, in the event of a meeting with an insurmountable obstacle. The energy of blows in the “Reverse” mode depends on the volume of the additional camera.

FIG. 2 schematically shows another example of the implementation of a reversible hammer action machine. It is a COOTOJIT lu. Case 1, a drummer 2, an air submersible hose 3 and a pneumatic pulsator equipped with a drive. In the inner cavity of the housing 1, the impactor 2 is placed with a possibility of movement in the main direction, which divides the cavity of the housing I into two working chambers: the front 4 and the rear 5.

The front working chamber communicates with the rear camera through a channel (not shown) of a small flow area, which can be performed, for example, in the drummer 2 in the form of a hole, a slit, etc. The rear working chamber 5 is in communication with the working cavity of the pulsator 6 by means of the air duct 3.

The main elements of the pulsator are body 7 and vytsitev 8. The body 7 of the pulsator can be made in the form of, for example, a cylinder, and the displacer 8 in the form of, for example, a piston. The displacer can move along the axis of the housing.

The displacer is kinematically connected to the engine through a mechanism that provides reciprocating motion, such as a crank-rod mechanism. The drive can be applied to any type of engine, such as electric.

On the side wall of the pulsator housing 1, there are two holes: the main compensation 9 and an additional 10. Through these compensation holes, the working cavity 6 of the pulsator can communicate with the external environment (atmosphere). The pulsator is equipped with a device 11 that provides the opening and closing of an additional compensation hole 10. The device 11 can be made in the form of a cork valve, valve, etc.

The reversible percussion machine shown in FIG. 2, works as follows.

When the engine is turned on, the displacer 8 moves reciprocally along the axis of the pulsator body 7 according to a periodic law. At the same time, the air pressure in the working cavity 6 of the pulsator, in the air supplying sleeve 3 and the rear working chamber 5 of the machine varies (at steady state) according to some periodic law with a period equal to the period of movement of the valve. Taking into account that the front 4 and rear 5 working chambers of the machine are interconnected by a channel of a small flow area, the pressure in these chambers does not match.

Under the action of a periodically varying pressure difference in the front 4 and rear 5 working chambers, the striker 2 reciprocates and, with the additional compensation hole 10 open, strikes the front part of the machine body 1. Under the action of these blows, the machine is introduced into the ground. Its reverse mixing is prevented by frictional forces between the hull and the ground. As a result, a well with compacted walls is formed. During the operation of the machine, the working cavity 6 of the pulsator during each working cycle communicates with the external environment through the main 9 and additional 10 holes. Switching the machine from the "Forward mode to the" Reverse mode is carried out in a simple way. For this purpose, the operator, using the device 11, closes the additional opening 10. As a result of the additional opening 10 being closed, the compression pulse in the pal 8 of the barrel cavity of the pulsator 6 becomes longer. This leads to a change in the shape of the pressure chart; in the working cavity of the pulsator and to change the mode of operation of the machine. The “Reverse. Run. Machine” mode works in the same way as in the “Forward travel” mode, with the only difference that drummer 2 strikes not the front part of housing 1, but the rear. Under the action of these blows, the machine moves in the opposite direction of the finished well. Thus, the machine is able to pierce deaf wells and can be returned from the seam, for example, in the event of an encounter with an insurmountable obstacle. The energy of impact in the “Reverse” mode of operation depends on the distance between the main 9 and additional 10 compensation holes.

Claims (4)

1. SHOCK ACTION MACHINE by ed. St. No. 1052627, characterized in that, in order to increase the efficiency of the machine by ensuring its reversal, it is equipped with a means for changing the shape of the diagram of air pressure in the working cavity of the pulsator. 2. Machine by π. 1, characterized in that the means for changing the shape of the diagram of air pressure in the working cavity of the pulsator is made in the form of a closed chamber in communication with the working cavity of the pulsator through a channel with a switch installed in it. 3. Machine by π. I, characterized in that the means for changing the shape of the diagram of air pressure in the working cavity of the pulsator is made in the form of an additional hole in the side wall of the pulsator housing with a switch. 4. The machine according to paragraphs. 2 and 3, characterized in that the switch is made in the form of a plug valve or valve. FIG. / Yu SU „„ 1106878>